Identifying Roadway Obstacles Based on Vehicular Data

ABSTRACT

Apparatuses, systems, and methods are provided for interfacing a roadway obstacle and navigation system with an obstacle identification and route determination system to identify roadway obstacles based on vehicular data. The roadway obstacle and navigation system may receive vehicular data through sensor utilization and communications with electronic devices. The vehicular data may be analyzed by the roadway obstacle and navigation system in conjunction with the obstacle identification and route determination system to identify roadway obstacles. The roadway obstacle and navigation system may use the roadway obstacles to provide safety alerts to drivers.

FIELD

Aspects described herein generally relate to one or more computersystems, servers, and/or other electronic devices including hardwareand/or software. In particular, aspects relate to evaluating vehiculardata to identify one or more roadway obstacles and, based on theidentified one or more roadway obstacles, causing a device to produce anaudible tone.

BACKGROUND

Community-based traffic and navigation applications allow users toactively report roadway obstacles encountered during driving so thatother users of the application may be apprised of such obstacles inadvance of potential encounters. In order to provide an obstacle report,however, users are required to manually enter information associatedwith the obstacle via a mobile device on which the application isoperating. Such a configuration, due to the requisite for active userinteraction, may contribute to distracted driving leading to motorvehicle accidents which, in some instances, may cause injury and/ordeath. Accordingly, in order to address such technological shortcomings,there may be a need for systems and methods for determining roadwayobstacles based on vehicular data without necessitating active userinput during vehicle operation.

BRIEF SUMMARY

The following presents a simplified summary of various aspects describedherein. This summary is not an extensive overview, and is not intendedto identify key or critical elements or to delineate the scope of theclaims. The following summary merely presents some concepts in asimplified form as an introductory prelude to the more detaileddescription provided below.

To overcome limitations in the prior art described above, and toovercome other limitations that will be apparent upon reading andunderstanding the present specification, aspects described herein aredirected to identifying roadway obstacles based on vehicular data.

Some aspects of the disclosure described herein provide for a roadwayobstacle and navigation system. The system may include one or morecomputing devices, such as a mobile device, an on-board computerassociated with a vehicle, or the like. The roadway obstacle andnavigation system may be configured to activate one or morecommunication interfaces and to pair, via the one or more communicationinterfaces, the mobile device or other computing device with atelematics device and/or vehicle on-board computer of the vehicle. Afterpairing, the roadway obstacle and navigation system may receive vehicleoperational data from the telematics device and/or vehicle on-boardcomputer. The roadway obstacle and navigation system may be furtherconfigured to determine whether the vehicle operational data surpasses apredetermined threshold. Responsive to doing so, the roadway obstacleand navigation system may compress the vehicle operational datasurpassing the threshold and transmit said data to an obstacleidentification and route determination system.

The roadway obstacle and navigation system may further be configured toreceive data from an obstacle identification and route determinationsystem corresponding to one or more roadway obstacles, determine alocation of the vehicle relative to the roadway obstacles, activate aspeaker based on the location of the vehicle relative to the roadwayobstacles being within a predetermined threshold, and cause the speakerto produce an audio tone in relation to the location of the vehiclerelative to the obstacles.

Additionally, the roadway obstacle and navigation system may beconfigured to receive navigation information from a user and to compressand transmit such information to the obstacle identification and routedetermination system. In response, the roadway obstacle and navigationsystem may receive directions between a location and a destinationwithin the navigation information, as well as information correspondingto one or more roadway obstacles. In order to provide alerts to a userregarding the one or more roadway obstacles, the roadway obstacle andnavigation system may be configured to activate speakers and cause thespeakers to produce an audible tone.

Other aspects of the disclosure described herein provide for an obstacleidentification and route determination system configured to interfacewith the roadway obstacle and navigation system. The obstacleidentification and route determination system may include an obstacleidentification server and a route determination server.

The obstacle identification server may be configured to receivevehicular data from one or more roadway obstacle and navigation systemsassociated with particular vehicles. Based on such data, the obstacleidentification server may be able to aggregate the vehicular data inrelation to the location and time at which the data was generated todetermine whether a roadway obstacle is present on any given segment ofroadway.

The route determination server may be configured to receive navigationinformation from one or more roadway obstacle and navigation systemsand, based on the navigation information, to produce a routedetermination. The route determination may further include data relatedto one or more roadway obstacles present on the route.

BRIEF DESCRIPTION OF THE DRAWINGS

A more complete understanding of aspects described herein and theadvantages thereof may be acquired by referring to the followingdescription in consideration of the accompanying drawings, in which likereference numbers indicate like features, and wherein:

FIG. 1 depicts an example roadway obstacle analysis system according toone or more aspects of the present disclosure.

FIG. 2 is a flow diagram illustrating an example of a driving eventdetermination method according to one or more aspects of the disclosure.

FIG. 3 is a flow diagram illustrating an example of a roadway obstacleidentification method according to one or more aspects of thedisclosure.

FIG. 4 is a flow diagram illustrating an example of a roadway obstaclealert and assessment method according to one or more aspects of thedisclosure.

FIG. 5 is a flow diagram illustrating another example of a roadwayobstacle alert and assessment method according to one or more aspects ofthe disclosure.

FIG. 6 is a flow diagram illustrating an example of a navigation methodaccording to one or more aspects of the disclosure.

FIG. 7 is a flow diagram illustrating another example of a navigationmethod according to one or more aspects of the disclosure.

FIGS. 8A and 8B depict example navigation interfaces according to one ormore aspects of the disclosure.

FIG. 9 illustrates an example network environment and computing systemsthat may be used to implement aspects of the disclosure.

DETAILED DESCRIPTION

FIG. 1 is a diagram illustrating various example components of a roadwayobstacle analysis system 100 according to one or more aspects of thedisclosure. The roadway obstacle analysis system 100 may include roadwayobstacle and navigation system 125, a network 130, and an obstacleidentification and route determination system 140. The roadway obstacleand navigation system 125 may include a vehicle 110 and one or morecomponents included therein or associated therewith (e.g., vehicleoperation sensors 111, GPS 112, telematics device 113, vehiclecommunication system 114, and on-board computer 115, and the like) andmobile computing device 120. The obstacle identification and routedetermination system 140 may include obstacle identification server 150and the components included therein or associated therewith (e.g.,obstacle identification computing device 152 and obstacle identificationdatabase 154) and route determination server 160 and the componentsincluded therein or associated therewith (e.g., route determinationcomputing device 162 and route determination database 164). The roadwayobstacle and navigation system 125 and the obstacle identification androute determination system 140 may be configured to communicate witheach other through network 130. Each component shown in FIG. 1 may beimplemented in hardware, software, or a combination of the two.Additionally, each component of the roadway obstacle analysis andnavigation system 100 may include a computing device (or system) havingsome or all of the structural components described below in regard tocomputing device 901 of FIG. 9.

Vehicle 110 of the roadway obstacle analysis system 100 may be anautomobile, motorcycle, scooter, bus, van, truck, semi-truck, train,boat, recreational vehicle, or other vehicle. The vehicle 110 mayfurther be an autonomous vehicle, semi-autonomous vehicle, ornon-autonomous vehicle. In some examples, vehicle 110 may includevehicle operation/performance sensors 111 capable of detecting,recording, and transmitting various vehicle performance and/oroperational data and environmental conditions data. For example, sensors111 may detect, store, and transmit data corresponding to the vehicle'sspeed, rates of acceleration and/or deceleration, braking, swerving, andthe like. Sensors 111 also may detect, store and/or transmit datareceived from the vehicle's internal systems, such as impact to the bodyof the vehicle, air bag deployment, headlight usage, brake lightoperation, door opening and closing, door locking and unlocking, cruisecontrol usage, hazard light usage, windshield wiper usage, horn usage,turn signal usage, seat belt usage, phone and radio usage within thevehicle, internal decibel levels, and other data collected by thevehicle's computer systems.

Sensors 111 also may detect, store, and/or transmit data relating tomoving violations and the observance of traffic signals and signs by thevehicle 110. Additional sensors 111 may detect, store, and transmit datarelating to the maintenance of the vehicle 110, such as the enginestatus, oil level, engine coolant temperature, odometer reading, thelevel of fuel in the fuel tank, engine revolutions per minute (RPMs),and/or tire pressure.

The sensors 111 of vehicle 110 may further include one or more camerasand proximity sensors capable of recording additional conditions insideor outside of the vehicle 110. Internal cameras may detect conditionssuch as the number of the passengers in the vehicle 110, and potentialsources of driver distraction within the vehicle (e.g., pets, phoneusage, and unsecured objects in the vehicle). External cameras andproximity sensors may be configured to detect environmental conditionsdata such as nearby vehicles, vehicle spacing, traffic levels, roadconditions and obstacles, traffic obstructions, animals, cyclists,pedestrians, precipitation levels, light levels, sun position, and otherconditions that may factor into driving operations of vehicle 110.

Additionally, vehicle sensors 111 may be configured to independentlytransmit the above-mentioned data to one or more computing devicesand/or systems including telematics device 113, on-board computer 115,mobile device 120, and/or obstacle identification and routedetermination system 140. In some instances, the data transmission tothe mobile device 120 and/or obstacle identification and routedetermination system 140 may be performed via on-board computer 115. Insuch cases, the on-board computer 115 may be configured to transmit thedata received from vehicle sensors 111 to mobile device 120 and/orobstacle identification and route determination system 140 by way ofvehicle communication system 114.

Vehicle 110 may include a Global Positioning System (GPS) 112 which maybe used to generate data corresponding to the position, heading,orientation, location, velocity, and/or acceleration of vehicle 110. GPS112 may be configured to independently transmit the above-mentioned datato one or more computing systems including telematics device 113,on-board computer 115, mobile device 120, and/or obstacle identificationand route determination system 140. In some instances, the datatransmission to the mobile device 120 and/or obstacle identification androute determination system 140 may be performed via on-board computer115. In such cases, the on-board computer 115 may be configured totransmit the data received from GPS 112 to mobile device 120 and/orobstacle identification and route determination system 140 by way ofvehicle communication system 114.

Telematics device 113 may be configured to receive vehicle performanceand/or operational data and environmental conditions data in the form ofa data stream from on-board computer 115 via a data port, Bluetoothinterface, or any comparable communication interface of the vehicle 110.For example, telematics device 113 may include an on-board diagnostic(OBD) device adapter and may be connected to an OBD port of the vehicle110 through which on-board computer 115 may be configured to transmitdata to telematics device 113. In certain embodiments, telematics device113 may be configured to receive vehicle performance and/or operationaldata and environmental conditions data directly from vehicle sensors111, GPS 112, on-board computer 115, and/or mobile device 120 via awired or wireless connection. Telematics device 113 may include a memoryto store data received from vehicle sensors 111, GPS 112, on-boardcomputer 115, and/or mobile device 120.

The vehicle performance and/or operational data may be collected withappropriate permissions (e.g., from the driver, vehicle owner, etc.) andmay include operational data from an industry standard port such as aSAE-1962 connector, or an on board diagnostic (“OBD”) port or othervehicle data acquiring component. For example, operation data accessiblevia the OBDII port includes speed and engine throttle position or othervariable power controls of the vehicle power source. It may also includeso called “extended OBDII” or OBDIII datasets that are specific to eachmanufacturer and also available with manufacturer permission such asodometer reading, seat belt status, activation of brakes, degree andduration of steering direction, etc., and implementation of accidentavoidance devices such as turning signals, headlights, seatbelts,activation of automated braking systems (ABS), etc. Other informationregarding the operation of the vehicle may be collected such as, but notlimited to, interior and exterior vehicle temperature, windowdisplacement, exterior vehicle barometric pressure, exhaust pressure,vehicle emissions, turbo blower pressure, turbo charger RPM, vehicle GPSlocation, etc. The system may recognize or be configured to recognize aparticular language emitted by the vehicle system and may configure therecording component to receive or convert data in SAE J1850, ISO ISO9141or KWP 2000 formats. Accordingly, U.S. and/or international OBDstandards may be accommodated. For instance, data may be collected froma variety of U.S. and/or international port types to permit use in avariety of locations. Alternatively, this step may be performed by aprocessor after the data is recorded.

Telematics device 113 may also include sensors such as, but not limited,an accelerometer, compass, gyroscope, and GPS. Additionally, telematicsdevice 113 may include antennas to communicate with other deviceswirelessly. For example, telematics device 113 may communicate withon-board computer 115, mobile device 120, and/or obstacle identificationand route determination system 140 over a wide area network (WAN),cellular network, Wi-Fi network, and the like. Telematics device 113 mayalso communicate with on-board computer 115 and mobile device 120 via aBluetooth connection. In certain embodiments, telematics device 113 maybe configured to establish a secure communication link and/or channelwith on-board computer 115, mobile device 120, and/or obstacleidentification and route determination system 140.

In some arrangements, telematics device 113 may include a telematicsapplication operating on on-board computer 115 and/or mobile computingdevice 120 and may utilize hardware components comprised within on-boardcomputer 115 and/or mobile computing device 120 (e.g., memory,processors, communication hardware, etc.) to receive, store, and/ortransmit vehicle performance and/or operational data and environmentalconditions data.

Vehicle communication systems 114 may be implemented using wirelessprotocols such as WLAN communication protocols (e.g., IEEE 802.11),Bluetooth (e.g., IEEE 802.15.1), one or more of the Communication Accessfor Land Mobiles (CALM) wireless communication protocols and airinterfaces, and the like. In certain systems, communication systems 114may include specialized hardware installed in vehicle 110 (e.g.,transceivers, antennas, etc.) to facilitate near field communication(NFC) and/or radio-frequency identification (RFID), while in otherexamples the communication systems 114 may be implemented using existingvehicle hardware components (e.g., radio and satellite equipment,navigation computers). In some instances, the vehicle communicationsystems 114 may be configured to transmit and receive data from vehiclesensors 111, GPS 112, telematics device 113, on-board computer 115,mobile device 120, and/or obstacle identification and routedetermination system 140 over a wide area network (WAN), cellularnetwork, Wi-Fi network, Bluetooth, RFID, and/or NFC.

On-board computer 115 may contain some or all of the hardware/softwarecomponents as the computing device 901 of FIG. 9. Vehicle controlcomputer 115 may be configured to operate one or more internal vehiclesystems and/or components including at least a vehicle sound system,dashboard display and/or heads-up display system, output speakers,interior lighting system, climate control system, ignition system, doorlocking system, and the like. Similarly, on-board computer 115 may beconfigured to operate one or more external vehicle systems and/orcomponents including windshield wipers, exterior lighting systems (e.g.,headlights, tail lights, running lights, turn signals, emergency lights,etc.), emission and exhaust systems, fuel systems, suspension systems,transmission systems, and the like. In some instances, vehicle controlcomputer 115 may be configured to perform the driving eventdetermination, roadway obstacle identification, and navigation methodsas described in further detail below in conjunction with mobilecomputing device 120 and/or obstacle identification and routedetermination system 140.

Additionally, on-board computer 115 may include a display screen forpresenting information to a driver of vehicle 110 pertaining to any of aplurality of applications such as a telematics application, roadwayobstacle and navigation application 117, and the like. In someinstances, the display screen may be a touch screen and may beconfigured to receive user touch input. Alternatively, the displayscreen may not be a touch screen and, instead, the on-board computer 115may receive user input and provide output through one or more of theinput/output modules 909 described in detail in regard to FIG. 9.

Mobile computing device 120 may be, for example, a mobile phone,personal digital assistant (PDA), or tablet computer associated with thedriver or passenger(s) of vehicle 110. As such, mobile computing device120 may be included within the vehicle 110 and, in some instances, maybe used to independently collect vehicle driving data and/or to receivevehicle driving and operational/performance data, environmentalconditions data, roadway obstacle and navigation data, and the like fromone or more computing systems (e.g., vehicle operation sensors 111, GPS112, telematics device 113, on-board computer 115, and/or obstacleidentification and route determination system 140). In one example,software applications executing on mobile computing device 120 (e.g.,telematics application and/or roadway obstacle and navigationapplication 117) may be configured to independently detect driving dataand/or to receive vehicle driving data and/or environmental conditionsdata, roadway obstacle and navigation data, and the like from one ormore internal and/or external computing systems. With respect toindependent vehicle data detection and collection, mobile device 120 maybe equipped with one or more accelerometers and/or GPS systems which maybe accessed by software applications executing on mobile computingdevice 120 to determine vehicle location (e.g., longitude, latitude, andaltitude), heading (e.g., orientation), velocity, acceleration,direction, and other driving data. As stated above, mobile computingdevice 120 may be configured to transmit the independently collectedvehicle driving data and/or the received vehicle driving data,environmental conditions data, roadway obstacle and navigation data, andthe like to one or more computing devices (e.g., telematics device 113,on-board computer 115, and/or obstacle identification and routedetermination system 140).

Additionally, mobile computing device 120 may be configured to performone or more of the methods and/or processes corresponding to drivingevent determination, roadway obstacle identification, roadway obstaclealert and assessment, and navigation as described in further detailbelow in conjunction with on-board computer 115 and/or obstacleidentification and route determination system 140. In some instances,the methods corresponding to the driving event determination, roadwayobstacle identification, roadway obstacle alert and assessment, andnavigation may be performed by a roadway obstacle and navigation system125 causing a roadway obstacle and navigation application 117 to operateor execute on mobile device 120. In performing such methods, mobiledevice 120 may be configured to detect and store vehicular operationaland navigation data, and may be further configured to transmit thevehicular operational and navigation data to on-board computer 115and/or obstacle identification and route determination system 140.Furthermore, mobile device 120 may be configured to receive vehicleoperational data, environmental conditions data, and/or data producedduring the performance of the methods corresponding to the driving eventdetermination, roadway obstacle identification, roadway obstacle alertand assessment, and navigation from sensors 111, GPS 112, telematicsdevice 113, on-board computer 115, and/or obstacle identification androute determination system 140.

The roadway obstacle analysis system 100 may include an obstacleidentification and route determination system 140 including an obstacleidentification server 150 and a route determination server 160. Theobstacle identification and route determination system 140 and each ofthe obstacle identification server 150 and the route determinationserver 160 may contain some or all of the hardware/software componentsas the computing device 901 of FIG. 9.

The obstacle identification and route determination system 140 may be asingle server containing some or all of the hardware/software componentsas the computing device 901 of FIG. 9. In such instances, each of theobstacle identification server 150 and the route determination server160 may be virtual machines operating on the obstacle identification androute determination system 140. Alternatively, the obstacleidentification and route determination system 140 may be a plurality ofservers containing some or all of the hardware/software components asthe computing device 901 of FIG. 9. In such instances, each of theobstacle identification server 150 and the route determination server160 may be individualized server entities.

In some instances, the analysis of the vehicular data in identifyingroadway obstacles and the analysis of the navigation information indetermining driving routes, as described in further detail below, may beperformed by obstacle identification and route determination system 140.In such instances, any one, or combination of, sensors 111, GPS 112,telematics device 113, on-board computer 115, and mobile device 120 maytransmit data to obstacle identification and route determination system140. Such data may include any of the above-mentioned vehicle drivingand operational/performance data, environmental conditions data,navigation data, and the like. Upon receipt of the data, obstacleidentification and route determination system 140, alone or incombination, with mobile device 120 and/or on-board computer 115 may beable to perform the processes outlined in FIGS. 2-7.

Obstacle identification server 150 may comprise an obstacleidentification computing device 152 configured to receive and processthe vehicle driving and operational/performance data and environmentalconditions data from one or more electronic devices (e.g., sensors 111,GPS 112, telematics device 113, on-board computer 115, and mobile device120) from each of a plurality of vehicles to determine whether or notroadway obstacles are present on any given segment of roadway mutuallydriven by each of the vehicles. The obstacle identification server 150may also comprise an obstacle identification database 154 in whichobstacle identification computer 152 is configured to store the vehicledriving and operational/performance data, environmental conditions data,and roadway obstacle data. Additionally, obstacle identification server150 may be configured to transmit data (e.g., roadway obstacle data) totelematics device 113, on-board computer 115, mobile device 120, androute determination server 160. In some instances, obstacleidentification server 150 may be optional and the processes performed byobstacle identification server 150 may be distributed to any one, orcombination of, mobile device 120 and on-board computer 115.

In particular, the obstacle identification server 150 may be configuredto analyze the driving data to identify various driving events thatoccurred during operation of each of a plurality of vehicles at anygiven point during the respective operation of the vehicles. Drivingevents may include, for example, acceleration events, deceleration(braking) events, turning events, lane change events, stopping events,backing up events, and the like which surpass a predetermined thresholdcorresponding to the event type. For instance, an acceleration event maycorrespond to a driving event if it surpasses a predetermined thresholdof more than 8 mph over a period of one second; a controlled brakingevent may correspond to a driving event if it surpasses a predeterminedthreshold of more than 8 mph over a period of one second; and a turningevent may correspond to a driving event if it surpasses a predeterminedthreshold of more than 1.025 g-forces. Such predetermined thresholds aslisted above are for illustrative purposes, and one of ordinary skill inthe art will readily appreciate that other predetermined thresholds maybe utilized. For example, an acceleration event may correspond to adriving event if it surpasses a predetermined threshold of more than 2,3.5, 5, or 7 mph over a period of one second; a controlled braking eventmay correspond to a driving event if it surpasses a predeterminedthreshold more than 2, 3.5, 5, or 7 mph over a period of one second; anda turning event may correspond to a driving event if it surpasses apredetermined threshold of more than 0.5, 0.65, 0.8, 0.95, or 1g-forces.

In further regard to acceleration events, such events may be associatedwith vertical, horizontal, and lateral acceleration and/or decelerationsurpassing a predetermined threshold. For example, if a vehicle swervesout of the way of an obstacle, a horizontal acceleration event may bedetermined if the acceleration data indicates that a predeterminedthreshold was surpassed. As noted above, in some examples, the roadwayobstacle and navigation application operating on the on-board computer115 and/or the mobile computing device 120 may perform some, or all, ofthe analysis of the driving data and provide indications of drivingevents.

The obstacle identification server 150 may further be configured todetermine whether an aggregate of driving events at a particularlocation signifies a roadway obstacle at the particular location. Inorder to associate the aggregate of driving events at a particularlocation with a roadway obstacle at the particular location, theobstacle identification server 150 may determine whether the determineddriving events at the particular location exceed a predeterminedthreshold of reported events (e.g., 10 or more driving events, 50 ormore driving events, 100 or more driving events, 500 or more drivingevents, etc. associated with a particular geographical location). In theevent that the obstacle identification server 150 determines that thedetermined driving events exceed a predetermined threshold of reportedevents, the obstacle identification server 150 may identify a roadwayobstacle at the particular geographical location.

Furthermore, the determination of a roadway obstacle may further be timedependent. For example, if the reported driving events exceed apredetermined threshold (e.g., 10 or more driving events, 50 or moredriving events, 100 or more driving events, 500 or more driving events,etc. associated with a particular geographical location) in a particulartime range (e.g., 2 hours, 5 hours, 24 hours, etc.), the obstacleidentification server 150 may determine that a roadway obstacle ispresent at the particular location. Additionally and/or alternatively,the determination of a roadway obstacle may be based on a percentage ofroadway obstacle identification and navigation systems 125 (e.g. 60% orgreater, 75% or greater, 85% or greater, etc.) providing vehicleoperational data determined to have surpassed the predeterminedthreshold over a particular time range (e.g., 2 hours, 5 hours, 24hours, etc.).

In some instances, the identified roadway obstacle may further beclassified as a permanent and/or temporary obstacle. For instance, apermanent obstacle may relate to a particular time of day (e.g., morningbetween 7:00 am-9:20 am, evening between 4:00 pm-7:00 pm, etc.) and/or aparticular segment of roadway (e.g., hairpin turn on a mountain road,speed bump, transitionary point from paved to gravel/dirt road, etc.). Atemporary obstacle may relate to roadway phenomena such as debris, a pothole, traffic accident, flooded roadway, and the like.

The route determination server 160 may comprise a route determinationcomputer 162 configured to receive and process navigation data (e.g.,trip and location data) from any one, or combination of sensors 111, GPS112, telematics device 113, on-board computer 115, and mobile device 120to determine a route from an entered location to an entered destinationcomprised within the trip data. In some instances, the determined routemay be a route involving the shortest total roadway travel distancebetween the entered location and destination. Alternatively, thedetermined route may be a route involving the least amount of roadwayobstacles between the entered location and destination. The routedetermination server 160 may also comprise a route determinationdatabase 164 used to store the route data produced by routedetermination computer 162, as well as the navigation data received fromany one, or combination of sensors 111, GPS 112, telematics device 113,on-board computer 115, and mobile device 120. Additionally, routedetermination server 160 may be configured to transmit data totelematics device 113, on-board computer 115, mobile device 120, andobstacle identification server 150. In some instances, routedetermination server 160 may be optional and the processes performed byroute determination server 160 may be distributed to any one, orcombination of, mobile device 120 and on-board computer 115.

The following steps that are described in regard to FIGS. 2-7 may beimplemented by one or more of the components of FIGS. 1 and 9 (describedin detail below) and/or other components, including other computingdevices configured to perform the functions described herein.Additionally, the methods corresponding to the driving eventdetermination, roadway obstacle identification, roadway obstacle alertand assessment, and navigation are recited in the singular (e.g., inrelation to a particular vehicle 110 associated with sensors 111, GPS112, telematics device 113, on-board computer 115, and mobile device120). However, one of ordinary skill in the art will readily appreciatethat the following description may be applied to a plurality ofvehicles, each of which being associated with sensors, GPS, telematicsdevice, on-board computer, and mobile device. Furthermore, while thecalculations for determining roadway obstacles based on vehicular dataand directions based on navigation data are discussed below in regardsto obstacle identification and route determination system 140 and, inparticular, the obstacle identification server 150 and the routedetermination server 160 comprised therein, such calculations may beperformed by any one, or combination of, the mobile device, server,telematics device, on-board computer, and the like.

FIG. 2 depicts a flow diagram illustrating an example of a driving eventdetermination method according to one or more aspects of the disclosure.In some examples, one or more aspects of the driving event determinationmethod, along with the roadway obstacle identification method, roadwayobstacle alert and assessment method, and navigation method described infurther detail below, may be included in and/or performed by the roadwayobstacle and navigation system 125. For instance, a roadway obstacle andnavigation application 117 downloaded from obstacle identification androute determination system 140 and executing on one or more of on-boardcomputer 115 and mobile device 120 of the system 125 may perform one ormore aspects described herein. The downloaded application may interfacewith obstacle identification and route determination system 140 androadway obstacle and navigation system 125 to perform one or more of theprocesses described herein. Additionally and/or alternatively, theroadway obstacle and navigation application 117 may be a web-basedapplication operating on obstacle identification and route determinationsystem 140. In such instances, on-board computer 115 and/or mobiledevice 120 may access a webpage associated with obstacle identificationand route determination system 140 in order to perform one or moreprocesses of the driving event determination method, roadway obstacleidentification method, roadway obstacle alert and assessment method, andnavigation method described herein. While the description of FIG. 2 isprovided in relation to mobile device 120, it should be understood thaton-board computer 115 or a combination of on-board computer and mobiledevice 120 may be able to perform the following functions.

At step 202, one or more communication interfaces (e.g., Bluetooth,WiFi, etc.) associated with mobile device 120 are activated after thelaunch of roadway obstacle and navigation application 117. In someinstances, the communication interfaces may be activated by the roadwayobstacle and navigation system 125. Additionally and/or alternatively,the communication interfaces may be activated by obstacle identificationand route determination system 140 via a web-browser accessing obstacleidentification and route determination system 140 operating on mobiledevice 120.

At step 204, after the one or more communication interfaces areactivated, the roadway obstacle and navigation system 125 may scan forthe presence of a telematics device 113 and/or on-board computer 115 ofa vehicle 110 in the proximity of the mobile device 120. In the eventthat a telematics device 113 and/or on-board computer 115 is detected oridentified during the scan conducted by the mobile device 120, theroadway obstacle and navigation system 125 may instruct the mobiledevice 120 to pair with the telematics device 113 and/or on-boardcomputer 115 at step 206.

Alternatively, if a telematics device 113 and/or on-board computer 115are not detected during the scan, the roadway obstacle and navigationsystem 125 may activate one or more sensors of mobile device 120 (e.g.,GPS system and an accelerometer) at step 208. As discussed below, thevehicular data used in performing the identification of roadwayobstacles may be determined by one or more of the activated GPS andaccelerometer.

At step 210, the roadway obstacle and navigation system 125 may receivevehicle operational data from the telematics device 113 and/or on-boardcomputer 115 of vehicle 110. In particular, such data may correspond tothe location (e.g., longitude, latitude, and altitude), heading (e.g.,orientation), velocity, and acceleration of the vehicle 110, as well asother data related to the operative state of vehicle systems such assteering, navigation, braking, and the like. In instances in which theroadway obstacle and navigation system 125 was unable to pair withtelematics device 113 and/or vehicle on-board computer 115, vehicleoperational data may be determined via one or more of the activated GPSsystem and accelerometer of the mobile device 120 associated withvehicle 110.

At step 212, in response to receiving the vehicle operational dataprovided by the telematics device 113 and/or on-board computer 115, theroadway obstacle and navigation system 125 may analyze the data todetermine if a driving event occurred (e.g., if the vehicle operationaldata surpasses a threshold of any of a plurality of types ofthresholds). As stated above, driving events may include accelerationevents, deceleration (braking) events, turning events, lane changeevents, stopping events, backing up events, and the like which surpass apredetermined threshold corresponding to the event type. In furtherregard to acceleration events, such events may be associated withvertical, horizontal, and lateral acceleration and/or decelerationsurpassing a predetermined threshold.

If, in step 212, one or more threshold are surpassed and a driving eventis determined to have occurred, the roadway obstacle and navigationsystem 125 may isolate the vehicle operational data corresponding to thedriving event including the value and type (e.g., vertical, horizontal,and lateral acceleration and/or deceleration) associated with the datasurpassing the threshold, as well as the geographical location and timeat which the data was determined in step 214. The system 125 may alsocompress the isolated data. The compression performed by the roadwayobstacle and navigation system 125 may be either lossy or lossless. Inparticular, compression may be performed using prefix codes, Huffmancodes, arithmetic coding, run-length coding, move-to-front coning,residual coding, context coding, Lempel-Ziv algorithms, Burrows Wheeleralgorithms, scalar and vector quantization, and/or wavelet, fractal, andmodel-based compression.

Alternatively, the determination of whether a driving event occurred maybe performed by obstacle identification server 150 of obstacleidentification and route determination system 140. In such instances,the roadway obstacle and navigation system 125 may be configured totransmit some, or all, of the vehicle operational data received fromtelematics device 113 and/or on-board computer 115 of vehicle 110 and/ordetermined independently at mobile device 120 to obstacle identificationserver 150 without performing the determination. The roadway obstacleand navigation system 125 may or may not compress the data prior totransmitting the data to obstacle identification server 150. In someinstances, the telematics device 113 and/or on-board computer 115 may beconfigured to directly transmit some, or all, of the vehicle operationaldata to obstacle identification server 150 without first transmittingthe vehicle operational data to the mobile device 120.

If, in step 212, the roadway obstacle and navigation system 125determines that the vehicle operational data does not surpass thepredetermined threshold and that a driving event has not occurred, theprocess may return to step 210.

At step 216, the roadway obstacle and navigation system 125 may transmitthe compressed vehicle operational data corresponding to the drivingevent to obstacle identification and navigation system 140. In order toconserve bandwidth, reduce processing power, and conserve energyexpenditure of mobile device 120, the data transmitted by the roadwayobstacle and navigation system 125 may only correspond to vehicleoperational data determined to have surpassed the predeterminedthreshold (e.g., vehicle operational data determined to relate to adriving event) at step 208. Moreover, by compressing the vehicleoperational data determined to have surpassed the predeterminedthreshold prior to transmittal, data usage may be further reduced.

FIG. 3 depicts a flow diagram illustrating a roadway obstacleidentification method according to one or more aspects of thedisclosure. The method of FIG. 3 at step 302 the obstacle identificationserver 150 of the obstacle identification and route determination system140 may receive compressed vehicle operational data from a pluralityroadway obstacle and navigation systems 125. Each of the plurality ofroadway obstacle and navigation systems 125 may be associated with aparticular vehicle. As stated above, the compressed data may correspondto vehicle operation data determined by the roadway obstacle andnavigation system 125 to have surpassed a predetermined threshold andcorrespond to a driving event. Alternatively, the obstacleidentification server 150 may receive vehicle operational data from anyone, or combination of, mobile device 120, telematics device 113, andon-board computer 115 respective to each of a plurality of vehicles ofeach of the plurality of roadway obstacle and navigation system 125, ineither a compressed or non-compressed state, wherein the vehicleoperational data has yet to have been determined to have surpassed thepredetermined threshold associated with a driving event.

In instances in which the compressed data was previously determined bythe roadway obstacle and navigation system 125 to have surpassed thepredetermined threshold and correspond to a driving event, the obstacleidentification server 150, upon receipt of the compressed data, maydecompress the data at step 304 via decompression algorithms that mirrorthe compression method performed by the roadway obstacle and navigationsystem 125 as described above in regard to step 214 of FIG. 2.

Conversely, in instances in which the data was not previously determinedby the roadway obstacle and navigation system 125 to correspond to adriving event, the obstacle identification server 150, in cases in whichthe data is compressed, may decompress the data at step 304 and mayanalyze the data to determine if a threshold of any of a plurality oftypes was surpassed (similar to step 212 in FIG. 2). As stated above,driving events may include acceleration events, deceleration (braking)events, turning events, lane change events, stopping events, backing upevents, and the like which surpass a predetermined thresholdcorresponding to the event type. In further regard to accelerationevents, such events may be associated with vertical, horizontal, andlateral acceleration and/or deceleration surpassing a predeterminedthreshold.

In the event that it is determined that a threshold is surpassed andthat a driving event occurred, the obstacle identification server 150may isolate the vehicle operational data corresponding to the surpassedthreshold including the value and type (e.g., vertical, horizontal, andlateral acceleration and/or deceleration) associated with the datasurpassing the threshold, as well as the geographical location and timeat which the data was determined.

Alternatively, in instances in which the data was not previouslydetermined by the roadway obstacle and navigation system 125 to havesurpassed the predetermined threshold, the obstacle identificationserver 150, in cases in which the data is not compressed, may notperform step 304 and instead may analyze the data to determine whether adriving event occurred.

The obstacle identification server 150 may store the vehicle operationaldata determined to have surpassed the predetermined threshold andthereby correspond to a driving event in obstacle identificationdatabase 154 in accordance with the geographical location and time atwhich the vehicle operation data was determined at step 306.

At step 308, the obstacle identification server 150 may identify, basedon the stored vehicle operational data entries determined to correspondto a driving event, whether a roadway obstacle is present at any of therespective locations associated with the stored vehicle operational dataentries. In the event that the stored data entries of vehicleoperational data corresponding to driving events surpass a predeterminedthreshold of entries (e.g., 10 or more stored entries, 50 or more storedentries, 100 or more stored entries, 500 or more stored entries, etc.associated with a particular geographical location), the obstacleidentification server 150 may identify a roadway obstacle at theparticular geographical location. The identified roadway obstacle mayfurther be classified as a permanent and/or temporary obstacle. Forinstance, a permanent obstacle may relate to a particular time of day(e.g., morning between 7:00 am-9:20 am, evening between 4:00 pm-7:00 pm,etc.) and/or a particular segment of roadway (e.g., hairpin turn on amountain road, speed bump, transitionary point from paved to gravel/dirtroad, etc.). A temporary obstacle may relate to roadway phenomena suchas debris, a pot hole, traffic accident, flooded roadway, and the like.

In some instances, the determination of a roadway obstacle may furtherbe time dependent. For example, if stored data entries provide datadetermined to have surpassed a predetermined threshold and therebycorrespond to a driving event at a particular geographical location in aparticular time range (e.g., 2 hours, 5 hours, 24 hours, etc.), theobstacle identification server 150 may determine that a roadway obstacleis present at the particular location. Additionally and/oralternatively, the determination of a roadway obstacle may be based on apercentage of roadway obstacle identification and navigation systems(e.g. 60% or greater, 75% or greater, 85% or greater, etc.) providingvehicle operational data determined to have surpassed the predeterminedthreshold over a particular time range (e.g., 2 hours, 5 hours, 24hours, etc.).

In the event that obstacle identification server 150 fails to identify aroadway obstacle, the process may return to step 302. Conversely, if theobstacle identification server 150 does identify a roadway obstacle, theprocess may proceed to step 310. At step 310, the obstacleidentification server 150 may store data corresponding to the identifiedroadway obstacle in the obstacle identification database 154.

At step 312, the obstacle identification server 150 may transmit datacorresponding to the identified roadway obstacle to each of the roadwayobstacle identification and navigation systems 125. The datacorresponding to the roadway obstacle may indicate the type of obstacle(e.g., permanent or temporary) and the location corresponding to theobstacle. In some instances, the data may be compressed by obstacleidentification server 150 prior to transmittal.

Additionally and/or alternatively, the obstacle identification server150 may determine whether to transmit data corresponding to theidentified roadway obstacle to one or more roadway obstacle andnavigation systems 125 in response to a periodic location updatecorresponding to the vehicle associated with each of the roadwayobstacle and navigations systems 125. The data comprising the periodiclocation update may include location information associated with thevehicle 110 and may be provided in set intervals (e.g., every 5 seconds,25 seconds, 1 minute, etc.). The obstacle identification server 150 mayanalyze the periodic location update information to determine if thevehicle associated with the roadway obstacle and navigation system 125has entered within a predetermined distance buffer (e.g., 1 mile, 5miles, 10 miles, etc.) around the location corresponding to theidentified roadway obstacle. In the event that the vehicle has enteredwithin the predetermined distance buffer, the obstacle identificationserver 150 may provide the data corresponding to the identified roadwayobstacle to the roadway obstacle and navigation system 125 correspondingto the vehicle.

FIG. 4 flow diagram illustrating an example of a roadway obstacle alertand assessment method according to one or more aspects of thedisclosure. At step 402, the roadway obstacle and navigation system 125may receive data corresponding to one or more roadway obstacles fromobstacle identification server 150. As stated above, the datacorresponding to the roadway obstacle may indicate the type of obstacle(e.g., permanent or temporary) and the location corresponding to theobstacle. In some instances, the data corresponding to the one or moreroadway obstacles may be compressed. In such instances, the roadwayobstacle and navigation operating 117 on mobile device 120 maydecompress the received data.

After receiving data corresponding to the one or more roadway obstacles,the roadway obstacle and navigation system 125 may determine a locationof the vehicle 110 at step 404. In determining the location of thevehicle 110, the roadway obstacle and navigation system 125 may requestlocation data of the vehicle 110 from telematics device 113 and/oron-board computer 115. Alternatively, in instances in which roadwayobstacle identification and navigation system 125 was unable to pairwith telematics device 113 and/or vehicle on-board computer 115,location data of vehicle 110 may be determined via the activated GPSsystem and accelerometer of the mobile device 120 associated withvehicle 110. In any case, the roadway obstacle and navigation system 125may determine a relative location of the vehicle 110 in relation to eachof the one or more roadway obstacles by comparing the data correspondingto the location of vehicle 110 to the location information of each ofthe one or more roadway obstacles at step 406.

At step 408, the roadway obstacle and navigation system 125 maydetermine whether the relative location of the vehicle 110 to at leastone of the one or more roadway obstacles is within a predeterminedthreshold (e.g., 1000 feet, 500 feet, 100 feet, etc.). In the event thatthe relative location of the vehicle 110 to the one or more roadwayobstacles is not within a predetermined threshold, the process mayreturn to step 404. Conversely, in the event that the relative locationof the vehicle 110 to at least one of the one or more roadway obstaclesis within a predetermined threshold, the process may proceed to step410.

At step 410, responsive to determining that the relative location of thevehicle 110 to at least one of the one or more roadway obstacles iswithin a predetermined threshold, the roadway obstacle and navigationsystem 125 may transmit a signal to mobile device 120 to activate aspeaker associated with mobile device 120. In some instances, roadwayobstacle and navigation system 125 may also activate a vibratorymechanism of mobile device 120. Additionally and/or alternatively, theroadway obstacle and navigation system 125 may transmit instructions toon-board computer 115 of vehicle 110 to activate a speaker system ofvehicle 110.

At step 410, based on the location of vehicle 110 approaching that of atleast one of the one or more roadway obstacles (e.g., the relativelocation between the vehicle 110 and the roadway obstacle decreasing),the roadway obstacle and navigation system 125 may cause the activatedspeaker of mobile device 120 to emit an audible tone of an increasingfrequency and loudness proportional to the relative distance between thevehicle 110 and the at least one of the one or more roadway obstacles.For instance, the roadway obstacle and navigation system 125 maytransmit a signal to the mobile device 120 to generate an audible signalor tone that may be emitted via the activated speaker. In someinstances, the roadway obstacle and navigation system 125 may also causethe vibratory mechanism of mobile device 120 to vibrate in proportion tothe relative distance between the vehicle 110 and the roadway obstacle.Such vibrations may be intermittent initially, but may approach aconstant vibratory state as the vehicle 110 approaches the obstacle(e.g., as a distance between the vehicle and the obstacle is reduced).Additionally and/or alternatively, the roadway obstacle and navigationsystem 125 may transmit instructions to on-board computer 115 of vehicle110 to produce an audible tone similar to that produced by mobile device120.

At step 412, after passing the at least one of the one or more roadwayobstacles, the roadway obstacle and navigation system 125 may compressvehicle operation data received from one or more of the telematicsdevice 113 and the on-board computer 115 corresponding to the locationof the at least one of the one or more roadway obstacles. In instancesin which the roadway obstacle and navigation system 125 was unable topair with telematics device 113 and/or vehicle on-board computer 115 andvehicle operational data is determined via one or more of the activatedGPS system and accelerometer of the mobile device 120 associated withvehicle 110, such data may be compressed as well.

After the vehicle operation data corresponding to the location of the atleast one of the one or more roadway obstacles is compressed by roadwayobstacle and navigation system 125, the compressed data may betransmitted by the roadway obstacle and navigation system 125to obstacleidentification server 150 at step 414.

FIG. 5 is a flow diagram illustrating another example of a roadwayobstacle alert and assessment method according to one or more aspects ofthe disclosure. The method of FIG. 5 may commence at step 502 whereinthe obstacle identification server 150 of the obstacle identificationand route determination system 140 may receive compressed vehicleoperational data from a plurality roadway obstacle and navigationsystems. Each of the plurality of roadway obstacle and navigationsystems may be associated with a particular vehicle. As stated above,the compressed data may correspond to vehicle operation datacorresponding to the location of the at least one of the one or moreroadway obstacles. Alternatively, the obstacle identification server 150may receive vehicle operational data from any one, or combination of,mobile device 120, telematics device 113, and on-board computer 115respective to each of a plurality of vehicles of each of the pluralityof roadway obstacle and navigation system 125, in either a compressed ornon-compressed state, corresponding to the location of the at least oneof the one or more roadway obstacles.

At step 504, upon receipt of the compressed data from the roadwayobstacle and navigation systems respective to each of a plurality ofvehicles, obstacle identification server 150 may decompress the data viadecompression algorithms that mirror the compression method performed bythe roadway obstacle and navigation system 125 as described above.Conversely, in instances in which the data was not compressed, theobstacle identification server 150 my skip step 504 and proceed to step506. At step 506, the obstacle identification server 150 may store thevehicle operational data in obstacle identification database 154 inrelation to the geographical position and time at which the data wasdetermined.

At step 508, the obstacle identification server 150 may determine, basedon the stored vehicle operation data corresponding to the location ofthe at least one of the one or more roadway obstacles, whether to removethe data corresponding to the at least one of the one or more roadwayobstacles stored in database 154. In performing the determination,obstacle identification server 150 may analyze each of the storedvehicle operational data entries corresponding to the location of the atleast one of the one or more roadway obstacles to determine whether ornot each of the stored vehicle operational data entries surpassed apredetermined threshold at the geographical location corresponding tothe roadway obstacle and thereby correspond to a driving event. In orderto remove the roadway obstacle, obstacle identification server 150 maydetermine that a particular threshold of stored data entries (e.g., 10or more stored entries, 20 or more stored entries, 100 or more storedentries, 500 or more stored entries, etc.) corresponding to the locationof the roadway obstacle did not surpass a predetermined data thresholdand do not correspond to a driving event. In some instances, thedetermination of whether or not to remove the roadway obstacle mayfurther be time dependent. For example, if stored data entries providedata determined not to have surpassed a predetermined threshold at thegeographical location corresponding to the at least one of the one ormore roadway obstacles in a particular time range (e.g., 2 hours, 5hours, 24 hours, etc.), the obstacle identification server 150 maydetermine that the roadway obstacle should be removed. Additionallyand/or alternatively, the determination of whether or not to remove aroadway obstacle may be based on a percentage of stored data entries(e.g. 60% or greater, 75% or greater, 85% or greater, etc.) providingvehicle operational data determined not to have surpassed thepredetermined threshold over a particular time range (e.g., 2 hours, 5hours, 24 hours, etc.).

In the event that obstacle identification server 150 determines not toremove the roadway obstacle, the process may return to step 502.Conversely, if the obstacle identification server 150 does determine toremove the roadway obstacle, the process may proceed to step 510. Atstep 510, the obstacle identification server 150 may transmit datacorresponding to the removal of the roadway obstacle to each of theroadway obstacle identification and navigation systems. The datacorresponding to the roadway obstacle may indicate that the obstacle hasbeen removed and the location corresponding to the obstacle. In someinstances, the data may be compressed by obstacle identification server150 prior to transmittal.

FIG. 6 is a flow diagram illustrating an example of a navigation methodaccording to one or more aspects of the disclosure. In step 602 theroadway obstacle and navigation system 125 may receive locationnavigation information (e.g., location and destination information) froma user through an input interface (e.g., touch screen, keypad, etc.) ofmobile device 120.

For example, as shown in FIG. 8A, the roadway obstacle and navigationsystem 125 may provide a navigation interface to a user including entryfield 802 corresponding to the location information (e.g., departureaddress), entry field 804 corresponding to the destination information(e.g., destination address), and map 806. In regard to step 602, theroadway obstacle and navigation system 125 may be configured to receivea departure address from the user in entry field 802 and a destinationaddress in entry field 804.

After receiving the navigation information, the roadway obstacle andnavigation system 125 may compress the received location and destinationinformation and transmit the compressed navigation information toobstacle identification and route determination system 140 and, inparticular, to route determination server 160 at step 604.

At step 606, the roadway obstacle and navigation system 125 may receiveroadway obstacle and route information from route determination server160 in relation to the location and destination information provided atstep 602. Additionally, and after receiving the roadway obstacle androute information, the roadway obstacle and navigation system 125 maygenerate and/or render the roadway obstacle and route information on thenavigation interface. For example, as shown in FIG. 8B, the roadwayobstacle and navigation system 125 may annotate map 806 with data points812 and 814 corresponding to the location and destination information,respectively, received from the user at step 602. Additionally, theroadway obstacle and navigation system 125 may generate any roadwayobstacles (e.g., 822 and 824, for example) determined by routedetermination server 160, as described in further detail below, alongthe determined route between data points 812 and 814 (e.g., location anddestination). The roadway obstacles 822 and 824 may be flags, pins,and/or other user interface elements. In some instances, the roadwayobstacles 822 and 824 may be of a particular color and/or type (e.g.,flag, pint, and/or other user interface elements) based on the class ofroadway obstacle which it signifies (e.g., temporary or permanentobstacle) and the type of obstacle within the class of roadway obstacle(e.g., pot hole, roadway debris, and the like for temporary obstaclesand traffic, speed bump, and the like for permanent obstacles).

At step 608, the roadway obstacle and navigation system 125 may activateone or more of a GPS system and an accelerometer associated with themobile device 120. As discussed below, the vehicle operational data andnavigation data used in performing the identification of roadwayobstacles and navigation functions may be determined by one or more ofthe activated GPS and accelerometer. At step 610, the roadway obstacleand navigation system 125 may determine, via one or more of theactivated GPS system and accelerometer, location information associatedwith a vehicle 110.

At step 612, the roadway obstacle and navigation system 125 maydetermine, based on the location information corresponding to thevehicle determined at step 610 and location information corresponding tothe roadway obstacles on the route between the location and destinationprovided by route determination server 160, whether the vehicle 110 isapproaching one or more of the roadway obstacles. In the event that theroadway obstacle and navigation system 125 determines that the vehicleis not approaching the location corresponding to the roadway obstacles,the process may return to step 610. Conversely, if the roadway obstacleand navigation system 125 determines that the vehicle 110 is approachinga roadway obstacle, the process may proceed to step 614.

At step 614, the roadway obstacle and navigation system 125 transmit asignal to mobile device 120 to activate a speaker associated with mobiledevice 120. In some instances, roadway obstacle and navigation systemmay also activate a vibratory mechanism of mobile device 120.Additionally, based on the location of vehicle 110 approaching that ofthe roadway obstacle (e.g., the relative location between the vehicle110 and the roadway obstacle decreasing), the roadway obstacle andnavigation system 125 may cause the activated speaker of mobile device120 to produce an audible tone of an increasing frequency and loudnessproportional to the relative distance between the vehicle 110 and the atleast one of the one or more roadway obstacles. In some instances, theroadway obstacle and navigation system 125 may also cause the vibratorymechanism of mobile device 120 to vibrate in proportion to the relativedistance between the vehicle 110 and the roadway obstacle. Suchvibrations may be intermittent initially, but may approach a constantvibratory state as the vehicle 110 approaches the obstacle.

At step 616, the roadway obstacle and navigation system 125 maydetermine that the vehicle 110 has reached the location corresponding tothe destination information received at step 602. Such a determinationmay be performed by matching the location information of vehicle 110 tothat of the previously provided destination. After determining that thevehicle has reached the location corresponding to the receiveddestination information, the roadway obstacle and navigation system 125may request, via the navigation interface, for the user to provideadditional information corresponding to the roadway obstaclesencountered during the drive at step 618. In particular, roadwayobstacle and navigation system 125 may request that the user provideinformation related to the class of the roadway obstacle which (e.g.,temporary or permanent obstacle) and the type of obstacle within theclass of roadway obstacle (e.g., pot hole, roadway debris, and the likefor temporary obstacles and traffic, speed bump, and the like forpermanent obstacles). In some instances, the roadway obstacle andnavigation system 125 may further request the user to provide anindication of the actuality of the roadway obstacle (e.g., whether theroadway obstacle existed and/or existed in the provided location).

At step 620, the roadway obstacle and navigation system 125 may compressthe user information provided by the user corresponding to the roadwayobstacle and may transmit such data to any one, or combination of,obstacle identification server 150 and route determination sever 160 instep 622.

FIG. 7 is a flow diagram illustrating another example of the navigationmethod according to one or more aspects of the disclosure. At step 702the route determination server 160 of the obstacle identification androute determination system 140 may receive compressed navigation data(e.g., location and destination information) from a roadway obstacle andnavigation system 125. Upon receipt of the compressed data, the routedetermination server 160 may decompress the data at step 704 viadecompression algorithms that mirror the compression method performed bythe roadway obstacle and navigation system 125 as described above.

At step 706, after decompressing the location and destinationinformation received from the roadway obstacle and navigation system125, the route determination server 160 may determine, based on thelocation and destination information, route information andcorresponding roadway obstacle information. In some instances, thedetermined route may be a route involving the shortest total roadwaytravel distance between the entered location and destination.Alternatively, the determined route may be a route involving the leastamount of roadway obstacles between the entered location anddestination. After determining the route information and associatedobstacle information, at step 708, the route determination server 160may transmit the data corresponding to the route information and theassociated roadway obstacles to the roadway obstacle and navigationsystem 125.

At step 710, the route destination server 160 may receive compresseddata comprising information regarding one or more of the roadwayobstacles associated with the route determined by the route destinationserver 160 in step 706. As stated above, such information may includeuser provided information related to the class of the roadway obstaclewhich (e.g., temporary or permanent obstacle) and the type of obstaclewithin the class of roadway obstacle (e.g., pot hole, roadway debris,and the like for temporary obstacles and traffic, speed bump, and thelike for permanent obstacles). In some instances, the data may furtherinclude an indication of the actuality of the roadway obstacle (e.g.,whether the roadway obstacle existed and/or existed in the providedlocation).

At step 712, the route destination server 160 may update, based on theuser provided information regarding one or more of the roadway obstaclesassociated with the determined route, information corresponding to oneor more of the roadway obstacles. For example, the information providedby the user may be used to update previously undetermined informationrelating to one or more of the roadway obstacles including the class andtype. In some instances, the user provided information may be used torevise the location data associated with the roadway obstacle, remove aroadway obstacle, and/or add a new roadway obstacle. In any event, theroute destination server 160 may be configured to store the updatedinformation corresponding to one or more of the roadway obstacles inroute destination database 164.

FIG. 9 illustrates a block diagram of a computing device 901 in aroadway obstacle analysis and navigation system that may be usedaccording to one or more illustrative embodiments of the disclosure. Thecomputing device 901 may have a processor 903 for controlling overalloperation of the computing device 901 and its associated components,including RAM 905, ROM 907, input/output module 909, and memory unit915. The computing device 901, along with one or more additional devices(e.g., terminals 941, 951) may correspond to any of multiple systems ordevices, such as roadway obstacle analysis and navigation systems,configured as described herein for performing methods corresponding tothe driving event determination, roadway obstacle identification,roadway obstacle alert and assessment, and navigation.

Input/Output (I/O) module 909 may include a microphone, keypad, touchscreen, and/or stylus through which a user of the computing device 901may provide input, and may also include one or more of a speaker forproviding audio input/output and a video display device for providingtextual, audiovisual and/or graphical output. Software may be storedwithin memory unit 915 and/or other storage to provide instructions toprocessor 903 for enabling device 901 to perform various functions. Forexample, memory unit 915 may store software used by the device 901, suchas an operating system 917, application programs 919, and an associatedinternal database 921. The memory unit 915 includes one or more ofvolatile and/or non-volatile computer memory to storecomputer-executable instructions, data, and/or other information.Processor 903 and its associated components may allow the computingdevice 901 to execute a series of computer-readable instructions toperform the methods described in FIGS. 2-7.

The computing device 901 may operate in a networked environment 900supporting connections to one or more remote computers, such asterminals/devices 941 and 951. Computing device 901, and relatedterminals/devices 941 and 951, may include devices installed invehicles, mobile devices that may travel within vehicles, or devicesoutside of vehicles that are configured to receive and process vehicleand other sensor data. Thus, the computing device 901 andterminals/devices 941 and 951 may each include personal computers (e.g.,laptop, desktop, or tablet computers), servers (e.g., web servers,database servers), vehicle-based devices (e.g., on-board vehiclecomputers, short-range vehicle communication systems, sensors andtelematics devices), or mobile communication devices (e.g., mobilephones, portable computing devices, and the like), and may include someor all of the elements described above with respect to the computingdevice 901. The network connections depicted in FIG. 9 include a localarea network (LAN) 925 and a wide area network (WAN) 929, and a wirelesstelecommunications network 933, but may also include other networks.When used in a LAN networking environment, the computing device 901 maybe connected to the LAN 925 through a network interface or adapter 923.When used in a WAN networking environment, the device 901 may include amodem 927 or other means for establishing communications over the WAN929, such as network 931 (e.g., the Internet). When used in a wirelesstelecommunications network 933, the device 901 may include one or moretransceivers, digital signal processors, and additional circuitry andsoftware for communicating with wireless computing devices 941 (e.g.,mobile phones, short-range vehicle communication systems, vehiclesensing and telematics devices) via one or more network devices 935(e.g., base transceiver stations) in the wireless network 933.

It will be appreciated that the network connections shown areillustrative and other means of establishing a communications linkbetween the computers may be used. The existence of any of variousnetwork protocols such as TCP/IP, Ethernet, FTP, HTTP and the like, andof various wireless communication technologies such as GSM, CDMA, Wi-Fi,and WiMAX, is presumed, and the various computing devices and componentsdescribed herein may be configured to communicate using any of thesenetwork protocols or technologies.

Additionally, one or more application programs 919 used by the computingdevice 901 may include computer executable instructions for receivingdata and performing other related functions as described herein.

As will be appreciated by one of skill in the art, the various aspectsdescribed herein may be embodied as a method, a computer system, or acomputer program product. Accordingly, those aspects may take the formof an entirely hardware embodiment, an entirely software embodiment oran embodiment combining software and hardware aspects. Furthermore, suchaspects may take the form of a computer program product stored by one ormore computer-readable storage media having computer-readable programcode, or instructions, embodied in or on the storage media. Any suitablecomputer readable storage media may be utilized, including hard disks,CD-ROMs, optical storage devices, magnetic storage devices, and/or anycombination thereof. In addition, various signals representing data orevents as described herein may be transferred between a source and adestination in the form of electromagnetic waves traveling throughsignal-conducting media such as metal wires, optical fibers, and/orwireless transmission media (e.g., air and/or space).

Although the subject matter has been described in language specific tostructural features and/or methodological acts, it is to be understoodthat the subject matter defined in the appended claims is notnecessarily limited to the specific features or acts described above.Rather, the specific features and acts described above are disclosed asexample forms of implementing the claims.

1. A method comprising: activating, by a roadway obstacle and navigationsystem including a roadway obstacle and navigation application executingon a mobile device associated with the roadway obstacle and navigationsystem, one or more communication interfaces of the mobile device;scanning, by the roadway obstacle and navigation system via the one ormore communication interfaces, for one or more of a telematics deviceand an on-board computer associated with a vehicle; responsive todetecting, via the scan, one or more of the telematics device and theon-board computer associated with the vehicle, pairing, by the roadwayobstacle and navigation system via the one or more communicationinterfaces, the mobile device with one or more of the telematics deviceand the on-board computer associated with the vehicle; receiving, by theroadway obstacle and navigation system from one or more of thetelematics device and the on-board computer, vehicle operational data ofthe vehicle; determining, by the roadway obstacle and navigation systemand based on the vehicle operational data, whether a driving eventoccurred; responsive to determining that a driving event occurred,compressing, by the roadway obstacle and navigation system, the vehicleoperational data corresponding to the driving event; transmitting, bythe roadway obstacle and navigation system, the compressed vehicleoperational data to an obstacle identification server; receiving, by theroadway obstacle and navigation system and from the obstacleidentification server, data corresponding to one or more roadwayobstacles, wherein the data corresponding to the one or more roadwayobstacles includes at least location information of each of the one ormore roadway obstacles; determining, by the roadway obstacle andnavigation system, a relative location of the vehicle in relation to thelocation information of each of the one or more roadway obstacles; anddetermining, by the roadway obstacle and navigation system, whether therelative location of the vehicle in relation to at least one of the oneor more roadway obstacles is within a predetermined threshold. 2.(canceled)
 3. The method of claim 1, further comprising: activating, bythe roadway obstacle and navigation system, a speaker of the mobiledevice based on determining that the relative location of the vehicle inrelation to at least one of the one or more roadway obstacles is withinthe predetermined threshold; and causing, by the roadway obstacle andnavigation system, the activated speaker to emit an audible tone of anincreasing frequency and loudness.
 4. The method of claim 1, furthercomprising: receiving, by the roadway obstacle and navigation system viaa touchscreen interface of the mobile device, location and destinationinformation from a user; transmitting, by the roadway obstacle andnavigation system, the location and destination information to a routedetermination server; and receiving, by the roadway obstacle andnavigation system and from the route determination server, routeinformation corresponding to the location and destination informationand data corresponding to one or more roadway obstacles along a routefrom a location indicated by the location information to a destinationindicated by the destination information of the route information. 5.The method of claim 4, further comprising: activating, by the roadwayobstacle and navigation system, one or more sensors of the mobile devicein response to receiving the route information and the datacorresponding to the one or more roadway obstacles; determining, by theroadway obstacle and navigation system via the one or more activatedsensors, location data of the vehicle in relation to at least one of theone or more roadway obstacles indicated in the data corresponding to theone or more roadway obstacles; and responsive to determining that thevehicle encountered at least one of the one or more roadway obstaclesbased on the location data determined via the one or more activatedsensors, requesting information from the user regarding the at least oneof the one or more roadway obstacles, wherein the requesting theinformation from the user occurs after the vehicle has reached thedestination.
 6. The method of claim 1, wherein the determining whetherthe driving event occurred further comprises: analyzing, by the roadwayobstacle and navigation application, the vehicle operational data of atleast one of a vertical, horizontal, and lateral acceleration of thevehicle in relation to a predetermined threshold corresponding to atleast one of the vertical, horizontal, and lateral acceleration of thevehicle.
 7. The method of claim 1, further comprising: determining, bythe roadway obstacle and navigation system, that one or more of thetelematics device and the on-board computer were not registered duringthe scanning; and activating, by the roadway obstacle and navigationsystem, one or more sensors of the mobile device.
 8. An apparatuscomprising: a processor; and memory storing computer readableinstructions that, when executed by the processor, cause the apparatusto: activate one or more communication interfaces of a mobile device;scan, via the one or more communication interfaces, for one or more of atelematics device and an on-board computer associated with a vehicle;pair, via the one or more communication interfaces, the mobile devicewith one or more of the telematics device and the on-board computerassociated with the vehicle; receive from one or more of the telematicsdevice and the on-board computer, vehicle operational data of thevehicle; determine, based on the vehicle operational data, whether adriving event occurred; responsive to determining that the driving eventoccurred, compress the vehicle operational data corresponding to thedriving event; transmit the compressed vehicle operational data to anobstacle identification server; receive data corresponding to one ormore roadway obstacles, wherein the data corresponding to the one ormore roadway obstacles includes at least location information of each ofthe one or more roadway obstacles; determine a relative location of thevehicle in relation to the location information of each of the one ormore roadway obstacles; and determine whether the relative location ofthe vehicle in relation to at least one of the one or more roadwayobstacles is within a predetermined threshold.
 9. (canceled)
 10. Theapparatus of claim 8, wherein the memory stores further computerreadable instructions that, when executed by the processor, cause theapparatus to: activate a speaker of the mobile device based ondetermining that the relative location of the vehicle in relation to atleast one of the one or more roadway obstacles is within thepredetermined threshold; and cause the activated speaker to emit anaudible tone of an audible tone of an increasing frequency and loudness.11. The apparatus of claim 8, wherein the memory stores further computerreadable instructions that, when executed by the processor, cause theapparatus to: receive via a touchscreen interface of the mobile device,location and destination information from a user; transmit the locationand destination information to a route determination server; and receivethe route determination server, route information corresponding to thelocation and destination information and data corresponding to one ormore roadway obstacles along directions from a location indicated by thelocation information to a destination indicated by the destinationinformation of the route information.
 12. The apparatus of claim 11,wherein the memory stores further computer readable instructions that,when executed by the processor, cause the apparatus to: activate one ormore sensors of the mobile device in response to receiving the routeinformation and the data corresponding to the one or more roadwayobstacles; determine, via the one or more activated sensors, locationdata of the vehicle in relation to at least one of the one or moreroadway obstacles indicated in the data corresponding to the one or moreroadway obstacles; and responsive to determining that the vehicleencountered at least one of the one or more roadway obstacles based onthe location data determined via the one or more activated sensors,requesting information from the user regarding the at least one of theone or more roadway obstacles, wherein the requesting the informationfrom the user occurs after the vehicle has reached the destination. 13.The apparatus of claim 8, wherein the memory stores further computerreadable instructions that, when executed by the processor, cause theapparatus to: analyze the vehicle operational data of at least one of avertical, horizontal, and lateral acceleration of the vehicle inrelation to a predetermined threshold corresponding to at least one ofthe vertical, horizontal, and lateral acceleration of the vehicle. 14.The apparatus of claim 8, wherein the memory stores further computerreadable instructions that, when executed by the processor, cause theapparatus to: determine that one or more of the telematics device andthe on-board computer were not registered during the scanning; andactivate one or more sensors of the mobile device.
 15. One or morenon-transitory computer-readable media having instructions storedthereon that, when executed, cause a computing device to: activate oneor more communication interfaces of a mobile device; scan, via the oneor more communication interfaces, for one or more of a telematics deviceand an on-board computer associated with a vehicle; pair, via the one ormore communication interfaces, the mobile device with one or more of thetelematics device and the on-board computer associated with the vehicle;receive from one or more of the telematics device and the on-boardcomputer, vehicle operational data of the vehicle; determine, based onthe vehicle operational data, whether a driving event occurred;responsive to determining that the driving event occurred, compress thevehicle operational data corresponding to the driving event; transmitthe compressed vehicle operational data to an obstacle identificationserver; receive data corresponding to one or more roadway obstacles,wherein the data corresponding to the one or more roadway obstaclesincludes at least location information of each of the one or moreroadway obstacles; determine a relative location of the vehicle inrelation to the location information of each of the one or more roadwayobstacles; and determine whether the relative location of the vehicle inrelation to at least one of the one or more roadway obstacles is withina predetermined threshold.
 16. (canceled)
 17. The one or morenon-transitory computer-readable media of claim 15, having additionalinstructions stored thereon that, when executed, further cause thecomputing device to: activate a speaker of the computing device based ondetermining that the relative location of the vehicle in relation to atleast one of the one or more roadway obstacles is within thepredetermined threshold; and cause the activated speaker to produce anaudible tone of an audible tone of an increasing frequency and loudness.18. The one or more non-transitory computer-readable media of claim 15,having additional instructions stored thereon that, when executed,further cause the computing device to: receive via the touchscreeninterface, location and destination information from a user; transmitthe location and destination information to a route determinationserver; and receive the route determination server, route informationcorresponding to the location and destination information and datacorresponding to one or more roadway obstacles along directions from alocation indicated by the location information to a destinationindicated by the destination information of the route information. 19.The one or more non-transitory computer-readable media of claim 18,having additional instructions stored thereon that, when executed,further cause the computing device to: activate one or more sensors ofthe mobile device in response to receiving the route information and thedata corresponding to the one or more roadway obstacles; determine, viathe one or more activated sensors, location data of the vehicle inrelation to at least one of the one or more roadway obstacles indicatedin the data corresponding to the one or more roadway obstacles; andresponsive to determining that the vehicle encountered at least one ofthe one or more roadway obstacles based on the location data determinedvia the one or more activated sensors, requesting information from theuser regarding the at least one of the one or more roadway obstacles,wherein the requesting the information from the user occurs after thevehicle has reached the destination.
 20. The one or more non-transitorycomputer-readable media of claim 15, having additional instructionsstored thereon that, when executed, further cause the computing deviceto: analyze the vehicle operational data of at least one of a vertical,horizontal, and lateral acceleration of the vehicle in relation to apredetermined threshold corresponding to at least one of the vertical,horizontal, and lateral acceleration of the vehicle.